2. History and Evolution of Controlled Hypotension Deliberate
hypotension was first introduced in 1917 in order to provide a
bloodless field for neurosurgery. In 1946, the concept of induced
hypotension using arteriotomy to produce a bloodless field was
introduced. In 1948, high spinal anaesthesia was use to induce
hypotension and create a dry field. in 1951 the high epidural block
was introduced. In 1962, sodium nitroprusside was first used to
induce hypotension during anaesthesia.
3. DEFINITION the level required to produce the effect but at
the same time is limited by safety Generally, it is taken that a
MAP as low as 50 mmHG or a 30% drop in MAP is safe for an ASA 1
subject. a chronic hypertensive patient who may not tolerate a drop
of more than 25 % of the MAP
4. PHYSIOLOGY Using the concept of MAP the physiology of these
3 systems needs to be examined separately to determine which is the
critical weak link i.e. the system that sets the minimal
permissible pressure. Flow is a function of both MAP and
autoregulation in the cerebral, myocardial and renal beds
5. Mechanisms of autoregulation 1. stretch- myogenic mechanism:
the smooth muscle in the vasculature responds to altered tension 2.
passive mechanical: applies to encapsulated organs, where expansion
of the organ with increasing pressure compresses thin walled
vessels and leads to an increase in vascular resistance. 3.
metabolic: changes in pressure produces vasoactive substances
6. organs capable of autoregulation are able to maintain their
perfusion over a wide range of pressure changes This critical
pressure varies from vessel to vessel, organ to organ, and probably
from individual to individual.
7. CEREBRAL CIRCULATION autoregulation normal cerebral blood
flow is maintained at 45-50mls/100g/min MAP range of
50-150mmHg
8. Factors influencing CBF PaCO2- For every 1mmHg increase in
PaCO2 there is an increase in CBF in the order of 1ml/100g/min and
vice versa
9. PaO2- 1. Changes in pao2 also alters CBF 2. 100% O2
administration in hyperbaric produce toxic effects on cerebral
function and 3. Reduces CBF by 1/5 4. Administration 100% O2 during
induced hypotension not beneficial
10. Volatiles Volatile anaesthetics attenuate or abolish the
autoregulation of cerebral blood flow in a dose dependent manner
inthe following order : halothane > enflurane >
isoflurane
11. TEMPERATURE: Cerebral blood flow changes 5-7% per degree
celcius change in temperature. Hypothermia causes cerebral
vasoconstriction whereas an increase in body temperature causes
cerebral vasodilation. VASODILATORS Vasodilators such as
nitroprusside and nitroglycerine attenuate the autoregulation of
CBF in a similar manner to that of volatile agents.
12. POSITIONING: Elevation of the head during hypotensive
anaesthesia can aggrevate the decrease in cerebral perfusion
pressure. The perfusion pressure decreases by 2mmHg for every 2.5cm
the head is raised above the point of monitoring
13. CORONARY CIRCULATION Coronary blood flow is dependent upon
the aortic diastolic blood pressure and the coronary vascular
resistance Control of coronary blood flow is autoregulated
predominantly by means of alteration in coronary vascular
resistance that are made to meet myocardial oxygen demand. any
increase in myocardial oxygen demand requires a parallel increase
in coronary artery blood flow
14. Hypotensive anaesthesia may substantially decrease coronary
blood flow. decreases myocardial oxygen demand Due to reduction in
afterload or preload
15. Patients with CAD may have areas of myocardium that are
entirely dependent upon pressure to supply adequate blood flow. use
of vasodilators in these patients may induce a steal phenomenon
significant intraoperative risk of myocardial infarction.
16. RENAL CIRCULATION Autoregulation over the range 80-180 mmHg
MAP less than 75 mmHg leads to decrease in GFR Opioids and
inhalational agents stimulate ADH release
17. HEPATIC CIRCULATION liver is not an autoregulated organ.
decrease in arterial pressure will lead to a decrease in liver
blood flow. An increase in PaCO2 or a decrease in PaO2 will lead to
a catecholamine response which causes splanchnic vasoconstriction
and therefore a decrease in liver blood flow. hypocapnia produced
incidentally by hyperventialtion during IPPV leads to a decrease in
liver blood flow as a result of the mechanical effects
18. liver blood flow may be altered directly by the effects of
anaesthetic agents on splanchnic blood flow
19. RESPIRATORY SYSTEM During controlled hypotensive
anaesthesia the following occurs: Pulmonary blood flow gravitates
to the dependent areas of the lungs. The use of vasodilators to
induce hypotension inhibits the hypoxic pulmonary vasoconstriction
response thereby increasing intra-pulmonary shunt. All these
factors result in hypercarbia, an increase in arterial-end tidal
CO2 gradient and hypoxaemia.
21. Anaesthetist factors Lack of understanding of the
technique. Lack of technical experience. Inability to monitor the
patient adequately.
22. Patient factors Cardiac disease . Diabetes . Anemia.
Hepatic disease. Ischaemic cerebrovascular disease. Renal disease.
Respiratory insufficiency. Severe systemic hypertension.
Intolerance to drugs used for hypotensive anaesthesia.
23. surgeons scale for the quality of surgical field 0 - no
bleeding, virtually bloodless field 1 - bleeding so mild it was not
even a surgical nuisance 2 - moderate bleeding, a nuisance but
without interference with accurate dissection 3 - moderate bleeding
that moderately compromised surgical dissection 4 - bleeding, heavy
but controllable, that significantly interfered with dissection 5 -
massive, uncontrollable bleeding
24. Techniques MAP = CO x SYSTEMIC VASCULAR RESISTANCE The key
equation in the provision of hypotensive anaesthesia . MAP can be
manipulated by reducing either SVR or Cardiac output or both.
25. METHODS TO REDUCE CARDIAC OUTPUT Reduction in blood volume
by arteriotomy Dilate the capacitance vessels using nitroglycerine
to reduce preload. Decrease in cardiac contractility using
inhalational agents or Beta blockers. Decrease in heart rate using
inhalational agents or Beta blockers
26. METHODS TO REDUCE PERIPHERAL VASCULAR RESISTANCE Blockade
of alpha adrenergic receptors eg. Labetalol, phentolamine.
Relaxation of vascular smooth muscle eg. Direct acting vasodilators
(nitroprusside), calcium channel blockers, inhalational agents,
purines (adenosine), prostaglandin E1.
27. Pharmacologic technique Ideal agent Ease of administration
Predictable & dose-dependent effect Rapid onset/offset Quick
elimination without the production of toxic metabolites Minimal
effects on blood flow to vital organs
29. Sodium nitroprusside Direct vasodilator (nitric oxide
release) Advantage Rapid onset/offset East to titrate Increases CO
Disadvantage Cyanide/thiocyanate toxicity Increased ICP Increased
pulm. shunt Sympathetic stimulation Rebound hypertension Coronary
steal Tachycardia
30. Nitroglycerin Direct vasodilator (nitric oxide release)
Advantage Rapid onset/offset East to titrate Limited increase in
heart rate No coronary steal Disadvantage Lack of efficacy-
depending on anesthetic technique Increased ICP Increased pulm.
shunt Methemoglobinemia Inhibition of plt. aggregation
31. Beta adrenergic antagonist Advantage Rapid onset/offset
Decreased myocardial O2 consumption No increase in ICP No increase
in pulm. shunt Disadvantage Decreased CO Heart block Bronchospasm
Limited efficacy when used alone
32. Calcium channel blocker - vasodilation Advantage Rapid
onset Limited increase in HR Increase CO No effect on airway
reactivity Increased GFR/urine output Disadvantage Prolonged
duration of action Increased ICP Increased pulm. shunt
33. MECHANICAL MANOEUVERS TO POTENTIATE THE ACTION OF
HYPOTENSIVE AGENTS Positioning: Position of the patient is
criticalto ensure success of the controlled hypotensive technique.
Elevation of the site of operation allows easy venous drainage from
the site of surgery. This is critical to ensure a bloodless field
change in blood pressure is at a rate of 0.77mmHg per cm change in
vertical height from the heart.
34. Positive airway pressure An attractive adjunct to
hypotensive anaesthesia is the use of positive pressure ventilation
1. with high tidal volumes, 2. prolonged inspiratory times and 3.
raising positive end expiratory pressure.
35. Anaesthetic management
36. Preoperative management Thorough knowledge by the
anaesthetist. Proper patient evaluation and selection. HB of 10
g/dl. Arterial blood gas analysis sampling. Good level of
anxiolytics ,analgesics . Vagolytic drugs should be avoided.
38. Monitoring Invasive blood pressure . ECG V5 lead with ST
segment analysis. Central venous pressure. Urine output.
Temperature. Blood loss.
39. Fluid therapy Proper fluid therapy is essential during
hypotensive anaesthesia. preoperative fluid statusmust be assessed
and corrected. At the same time maintenance volumes need tobe
infused. Blood loss must be replaced with an equal amount of
colloid or three to four times the amount of crystalloid. If the
blood loss exceeds a predetermined level ( eg. 20-25% of
thepatients total blood volume ), a blood transfusion is
warranted
41. CONCLUSION advantage of miminimisng blood loss during
surgery thereby reducing blood transfusion requirements. an
improved surgical field results thereby improving surgical
technique and dissection and reducing the need for
electrocauterization. reduce post operative pain and sepsis. It is
also a safe technique provided appropriate patient evaluation and
selection, proper positioning and monitoring and adequate fluid
therapy .